Method For 3-D Printing A Custom Bone Graft

ABSTRACT

A method for producing bone grafts using 3-D printing is employed using a 3-D image of a graft location to produce a 3-D model of the graft. This is printed using a 3-D printer and a printing medium that produces a porous, biocompatible, biodegradable material that is conducive to osteoinduction. For example, the printing medium may be PCL, PLLA, PGLA, or another approved biocompatible polymer. In addition such a method may be useful for cosmetic surgeries, reconstructive surgeries, and various techniques required by such procedures. Once the graft is placed, natural bone gradually replaces the graft.

CLAIM OF PRIORITY

This application is a continuation application of non-provisional patentapplication Ser. No. 16/395,273, titled “Method for 3-D printing acustom bone graft”, filed in the United States Patent and TrademarkOffice on Apr. 26, 2019, which is a divisional application ofnon-provisional patent application Ser. No. 15/285,169, titled “Methodfor 3-D printing a custom bone graft”, filed in the United States Patentand Trademark Office on Oct. 4, 2016, which is a continuation in partapplication of non-provisional patent application Ser. No. 14/447,085,titled “Method for 3-D printing a custom bone graft”, filed in theUnited States Patent and Trademark Office on Jul. 30, 2014, which claimspriority to provisional patent application No. 61/867,755, titled“Method for 3-D printing a custom bone graft”, filed in the UnitedStates Patent and Trademark Office on Aug. 20, 2013, the contents of allof which are hereby fully incorporated by reference in their entirety.

FIELD OF THE EMBODIMENTS

The field of the invention and its embodiments relate to producing acustom bone graft, and more particularly to methods of producing custombone grafts or implants using 3-D printing. In particular, the presentinvention may be useful for reconstructive surgeries and cosmeticsurgeries, and any other procedure requiring such augmentation.

BACKGROUND OF THE EMBODIMENTS

Bone grafting is possible because bone tissue, unlike most othertissues, has the ability to regenerate completely if provided the rightenvironment, including a space into which to grow, or a matrix to growon. As native bone grows, it replaces the graft material, so that overtime, the graft is replaced by a fully integrated region of new bone.

Bone regeneration occurs through osteoinduction, a process in whichconnective tissue is converted into bone by an appropriate stimulus.Osteoinduction allows bone formation to be induced even at non-skeletalsites and is initiated by bone morphogenetic proteins (BMP).

The ideal bone graft material would be a strong, porous biocompatiblematerial infused with BMP that did not cause inflammation and wouldultimately be reabsorbed into the body as it is replaced by naturalbone.

Bone is composed of 50 to 70% inorganic mineral, 20 to 40% organiccollagen matrix, 5 to 10% water, and <3% lipids. The inorganic mineralcontent of bone is mostly hydroxyapatite[Ca.sub.10(PO.sub.4)6(OH).sub.2]. The inorganic mineral provides themechanical strength and rigidity, whereas the organic collagen matrixprovides elasticity and flexibility.

Demineralized bone matrix (DBM) is allograft bone, i.e., bone from otherhumans, that has had the inorganic, mineral material removed, leavingbehind the organic collagen matrix and the BMPs that induceosteoinduction. DBM is conducive to osteoinduction, but lacks the loadbearing strength. It is typically used with a 2-4% hyaluronate carrieras a paste or putty to fill a space needing bone, and allows real boneto grow into it within weeks to months.

The present invention provides a system and method of producing custombone grafts that are made of a porous, biocompatible material infusedwith BMPs that can be used as ink in a 3-D printer to produce bonegrafts of any desired shape.

REVIEW OF RELATED ART

U.S. Patent Application 2011/0151400 published by A. Boiangiu et al. onJun. 23, 2011 entitled “Dental Bone Implant, Methods for Implanting theDental Bone Implant and Methods and Systems for Manufacturing DentalBone Implants” pertains to a dental bone implant having a first fittedbone graft sized and shaped to fit tightly to a buccal surface of aperiodontal alveolar bone around at least one tooth and to reconstructat least a portion of one or more periodontal bone defect and a secondfitted bone graft sized and shaped to fit tightly to a lingual/palatalsurface of a periodontal alveolar bone around at least one tooth and toreconstruct at least an additional portion of at least one periodontalbone defect. The portion and the other portion complementary cover theone or more periodontal bone defects.

U.S. Patent Application 2004/0120781 published by S. Luca et al. on Jun.24, 2004 entitled “Customized instruments and parts for medical-dentalapplications and method and blank for on-site machining of same”pertains to a customized prosthesis, or instrument, for medical/dentalapplications which replicates the desired bone-graft, tooth, or tool,being replaced. The dimensions of the prosthesis, or instrument, aredetermined by mathematically interpolating key-points that characterizea specific part. A computer controlled machine then cuts the desiredpart out of a pre-fabricated blank, directly at the site of operation.Methods of the invention relate to selecting the type of part beingreplaced, identifying and measuring the coordinates of key-points forthat part, and initializing the automated machining process. Also,special supporting devices that include pre-fabricated features commonbetween certain parts are used in order to facilitate the machiningprocess. The identification of key-points is done by comparing aschematic drawing of the type of part being replaced to the actual part.A grid is then used to measure the coordinates for those key-points.

U.S. Pat. No. 6,671,539 issued to Gateno et al. on Dec. 30, 2003entitled “Method and apparatus for fabricating orthogenetic surgicalsplints” pertains to a method of forming a surgical splint to receive apatient's dentition and thereby align the upper jaw and the lower jawduring surgery includes generating a CT computer model of bonestructure, generating a digital dental computer model of the patient'sdentition, and then combining the CT computer model and the digitaldental computer model to form a composite computer model. The compositecomputer model may be displayed, and at least one of the upper jaw andlower jaw repositioned relative to the patient's skull and the compositecomputer model to form a planned position computer model. Using thisdesired position computer model, a computer model surgical splint of thepatient's dentition may be formed, which is then input into afabrication machine to form a surgical splint. The method also includesforming and displaying the composite computer model. A workstationincludes a CT machine, a digital scanner, a computer, an input commandmechanism, a display, and a fabricating machine.

U.S. Pat. No. 8,021,154 issued to Holzner et al. on Sep. 20, 2011entitled “Method for manufacturing dental prostheses, method forcreating a data record and computer-readable medium” pertains to amethod for manufacturing one or several dental prostheses, comprisingthe steps of: performing a rapid prototyping method for manufacturingone or several dental prostheses and subsequent working, such asreworking, of the one or several dental prostheses with a machiningmethod, such as a milling method. In addition, a method for creating adata record which can be used for a rapid prototyping method formanufacturing a dental prosthesis wherein an end data record is obtainedfrom a starting data record, so that in at least one area of a dentalprosthesis manufactured with the end data record excess material isprovided, compared to a dental prosthesis manufactured with the startingdata record.

Various implements are known in the art, but fail to address all of theproblems solved by the invention described herein. One embodiment ofthis invention is illustrated in the accompanying drawings and will bedescribed in more detail herein below.

SUMMARY OF THE EMBODIMENTS

The present invention describes systems and methods for producing acustom bone graft for at least reconstructive and cosmetic surgeries.The present embodiments may be particularly useful for “donut” typeimplant insertions and for printing grafts for sinus lifts.

In one embodiment of the present invention there is a method forproducing a custom bone graft, comprising: obtaining a 3-D image of anintended graft location; creating a 3-D mesh using said 3-D image;creating a 3-D digital model of said custom bone graft using said 3-Dimage; and creating, using said 3-D digital mold and a porous,biodegradable, biocompatible material that is conducive toosteoinduction and has a load bearing strength comparable to bone, toproduce said custom bone graft.

In another embodiment of the present invention there is a method forproducing a custom bone graft, comprising: obtaining an image of anintended graft location; creating a digital model of said custom bonegraft using said image; and creating, using a 3-D printer said custombone graft using a printing medium that forms a porous material that hasa load bearing strength comparable to bone.

In one preferred embodiment, a 3-D image of an intended graft locationmay be obtained. This may be achieved by a number of methods, some ofwhich may be discussed in further detail later. Use may, for instance,be made of 3-D image construction techniques such as, but not limitedto, obtaining multiple 2-D X-ray images at different orientations, andusing computational techniques to convert these into a 3-D image, usinga Cone beam imaging device or a cat-scan device, or some combinationthereof.

This 3-D image of the graft location may then be converted into a 3-Ddigital image of the custom bone graft.

The custom bone graft may be printed directly using a modified 3-Dprinter and an ink that transforms into a suitable porous,biocompatible, biodegradable material that is conducive toosteoinduction and has a load bearing strength comparable to bone.

The custom bone graft may also or instead be made by using a 3-D printerto print a negative form or mold, and the mold may then be used toproduce the custom bone graft. In such a process, in a preferredembodiment, the mold may be filled with a mixture of, for instance,Calcium Sulfate hemihydrate, aka Plaster of Paris, demineralized freezedried bone (DFDB), or freeze dried bone (FDB), Bone MorphogeneticProteins (BMP) and an antibiotic such as, but not limited to,Doxycycline.

In a preferred embodiment, the porous, biocompatible material may beporous Poly Methyl Methacrylate (PMMA) and demineralized allograft bonematrix (DMB). The ink for this material may, for instance, be providedas a precursor powder, and a precursor liquid. The precursor powder may,for instance, include demineralized allograft bone matrix (DMB), sucrosecrystals and a radical polymerization initiator. The precursor liquidmay, for instance, include Methyl Methacrylate (MMA) as well as one ormore antibiotics and one or more radio-pacifiers, i.e., compounds thatmake the graft more radio opaque, or radio dense, so that it may be morevisible on X-ray images.

In a preferred embodiment, the radical polymerization initiator may bebenzoyl peroxide, the antibiotic may be gentamicin and theradio-pacifier may be barium sulphate.

The precursor liquid and powder may be mixed in small batches to producethe ink just before printing. Once the precursors are mixed the MMA maystart to polymerize to PMMA. The viscosity of the liquid will increasewith time, but suitably proportioned, the ink may be delivered through a10-14 gauge needle or print nozzle for about 10 to 20 minutes. This mayprovide a dot size of about 2 mm in diameter, which may be theresolution of the finest detail of the custom bone graft.

The sucrose crystals provide the porosity to the structure when they aredissolved out in post print processing.

The structure printed by the ink may also be made biodegradable by theinclusion of cellulose acetate (CA) or cellulose acetate phthalate(CAP), or a combination thereof. The biodegradability may allow theporous PMMA structure to be replaced by natural bone over time.

Therefore, the present invention succeeds in conferring the following,and others not mentioned, desirable and useful benefits and objectives.

It is an object of the present invention to provide custom bone graftssuitable for use in disciplines such as, but not limited to,Orthopedics, Plastic Surgery, ENT and Dentistry.

It is a further object of the present invention to be of use inprocedures, including plastic surgery procedures, such as, but notlimited to, cleft palate surgical repair, facial and non-facial posttrauma or tumor removal reconstruction.

It is an object of the present invention to provide a method ofproducing custom bone grafts at a reasonable price.

It is a further object of the present invention to provide bone graftsthat may be an intimate fit to the graft site, as this may increase thechances of bone graft maturation and healing, and because intimatecontact is one predictor of a successful surgery.

It is another object of the present invention to provide a method ofproducing a custom bone graft using equipment that may be located at asurgeon, or plastic surgeon's, site or office.

It is an object of the present invention to provide suitable ink for usein suitably modified 3-D printers.

It is a further object of the present invention to design and fabricatebone grafts to add lost tissue or tissue that was never developed.

It is a further object of the present invention to design and fabricategrafts for a sinus lift.

It is a further object of the present invention to design and fabricateimplants for cosmetic procedures.

It is a further object of the present invention to provide grafts and/orimplants for reconstructive surgery.

It is a further object of the present invention to provide fordonut-type insertions of implants and/or grafts.

It is a further object of the present invention to provide a printingmethod that uses extrusion of the printing medium.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a preferred embodiment of a method for producing a custombone graft.

FIG. 2 shows a magnified section of the mineral structure of bone.

FIG. 3 shows a magnified section of a demineralized allograft bonematrix (DMB).

FIG. 4 shows a magnified section of a porous, biocompatible materialsuitable for use as a bone graft.

FIG. 5 shows a magnified section of an intermediate stage in producingporous Poly Methyl Methacrylate (PMMA).

FIG. 6 shows a sematic layout of the ink mixing and print nozzle of apreferred embodiment of the present invention.

FIG. 7 shows a sematic flow diagram of representative steps of apreferred embodiment of the present invention.

FIG. 8 shows a cone-beam scan of a patient used by computer software toproduce an image of a bone defect.

FIG. 9 shows a sectional view of a 3-D reconstruction of an imageddefect.

FIG. 10 shows a sectional view of a computer generated 3-D positiveimage of a required graft.

FIG. 11 shows a sectional view of a negative mold of a required graft.

FIG. 12 shows a sectional view of a negative mold being used to producea required graft.

FIG. 13 shows a sectional view of a graft being placed during surgery.

FIG. 14A shows a required complex long bone graft.

FIG. 14B shows a negative mold for a portion of the required complexlong bone graft.

FIG. 14C shows a negative mold being used to produce a portion of therequired complex long bone graft.

FIG. 14D shows a negative mold being used to produce a portion of therequired complex long bone graft.

FIG. 15 illustrates a sectional side view of an embodiment of a syringein accordance with the present invention.

FIG. 16A illustrates a porous grid printed with a layer rotationmethodology.

FIG. 16B illustrates a porous grid printed with a layer sidesteppingmethodology.

FIG. 16C illustrates a sectional side view of an interconnection of aporous grid.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The preferred embodiments of the present invention will now be describedwith reference to the drawings. Identical elements in the variousfigures are identified with the same reference numerals.

Various embodiments of the present invention are described in detail.Such embodiments are provided by way of explanation of the presentinvention, which is not intended to be limited thereto. In fact, thoseof ordinary skill in the art may appreciate upon reading the presentspecification and viewing the present drawings that variousmodifications and variations can be made thereto.

FIG. 1 shows a preferred embodiment of a method for producing a custombone graft. An X-ray imaging machine 155 may be used to take one or moreimages of a region of a patent where a custom bone graft 120 may beneeded. These may then be assembled into a 3-D image 105 of the regionrequiring a custom bone graft 120. A suitably programmed digitalprocessor 240 may take the 3-D image 105 and transform it into a 3-Dmodel of the region requiring the custom bone graft 120. This 3-D modelmay then be used to generate a 3-D model of the required custom bonegraft 120. This 3-D model of the required custom bone graft 120 may thenbe used by a software module operative on the digital processor 240 togenerate instructions for a 3-D printer 115. These instructions may, forinstance, take the form of a 3-D digital model 110 made up of a seriesof layers 245. These layers of a 3-D digital model 245 may, forinstance, be sized to the resolution of the 3-D printer 115 that may beused to generate the custom bone graft 120.

The 3-D printer 115 may be configured to apply the printing medium orink, as noted above, in layers or a series of layers. In someembodiments the 3-D printer 115 may operate using an extrusiondeposition method, fusing of granular materials, laminationmethodologies, photopolymerization methodologies, or continuous liquidinterface production methodologies. Preferably, the 3-D printer 115 hasa compound heating element which comprises at least two components: 1)printer portion and 2) application or syringe portion. This allows forextrusion printing techniques to be accomplished and the use ofcompatible materials for such techniques.

The 3-D printer 115 may then be used to produce the custom bone graft120 layer by layer using an appropriate ink, or series of inks. The 3-Dprinter may have a number of parts/components including an infectioncontrol mechanism to prevent contamination of the printed graft and theprinter components. Preferably there is a hood or venting hood which canbe closed over and around the printing mechanism that is coupled to amedical grade HEPA filter. Sterile or clean air can then be drawn intothe hood via the HEPA filter and removed via a surgical-type suctionconnection. Such a process will prevent or limit the chance ofcontamination of the graft and printing components/surfaces withpathogens.

In one embodiment, a 3-D printer 115 uses a syringe 500 (see FIG. 15) toapply the printing material. The syringe may come in varying sizes suchas 0.5 cc, 1.0 cc, 1.5 cc, 2.0 cc, 2.5 cc, and 3.0 cc. In someembodiments, different sizes, including those over 3.0 cc may beemployed.

Referring now to FIG. 15, the syringe 500 (shown in a sectionalsideview) preferably has a plunger (not shown) comprised of at least oneFDA approved material and a barrel 505 coated with or comprised whollyof Teflon® or other low friction FDA approved material(s). Thiscomposition/coating helps to allow for full extrusion of the printingmaterial/medium 510 or ink from the syringe 500. Further, the plungermay vary in size, in relation to the size of the barrel, to effectuatethis full extrusion. The plunger or piston may be advanced or retractedby the printer.

The syringe 500 is intended to be a single or one time use syringe, andis preferably kept under sterile conditions (e.g. packaging) until thegraft is ready to be printed. Such a syringe 500 is fully assembled(plunger, printing medium contained within barrel, etc.) and ready foruse out of the packaging. In some embodiments, chips, codes (bar code,QR code, etc.) may be used to identify/verify the syringe and itscontents before use.

In some embodiments, the printing material 510 may be in the form of asolid “rod” which is heated by at least one heating element allowing thesolid or semi-solid printing material 510 to be extruded by increasing atemperature of the material to approximately its melting point. Thus,the syringe 500 has a heated head or tip 520 that allows more viscous orsolid or semi-solid printing materials to be easily extruded through thesyringe tip 520. This heated head is preferably made of a metal ormetals with the nozzle or tip being shaped to allow the printingmaterial or ink to pass therethrough. The heated head 515 is heated viaa heating mechanism 525 of the 3-D printer. The heated head 515 allowsfor heat to be transferred or conducted thereby causing the printingmedium 510 to soften or melt. The heating mechanism further hastemperature sensors or thermostats 530 that will provide feedback to theprinter/software allowing for modifications to temperature to be made inreal time throughout the printing process.

A locking mechanism will ensure that an operable connection isestablished and maintained between the headed head of the syringe 500and the heating mechanism 525 of the printer. The locking mechanism maybe a latch or lock that can be electronically or manually positioned. Inother embodiments, the locking mechanism is defined by a shape of theheated head and a complementary shape of the heating mechanism whichinteract to provide this locking feature.

The syringe “pump” or piston is preferably comprised of an FDA approvedmaterial and mechanism. This may comprise hydraulics, mechanicalmovements, or some combination thereof. The syringe may be coupled tothe printer via a robotic arm and may use magnets to allow for easychanging of the syringe.

In a preferred embodiment the printing medium or inks includepolycaprolactone (PCL), polylactic acid (PLLA), polylactic-co-glycolicacid (PLGA) or other FDA approved biodegradable materials. Preferablythe printing medium is PCL.

Referring now back to FIG. 1, in at least one embodiment, the printingis done in an offset grid configuration to allow for blood vessel growthand permeation through the graft and/or implant. This is achieved byside stepping or rotating of the direction of the printed layers. Such aprinting configuration allows for up to 100% penetration of the graftingmaterial(s) and any required medications.

The surface of the printer, on which the graft is printed, is preferablya sterile, disposable printing surface. In at least one embodiment theprinting surface or tray is comprised of boric silica glass with apolyethylene terephthalate (PET) coating. The size of the tray may varybut is preferably about 100 mm times.100 mm. The tray may also bethermally manipulated to meet certain temperature conditions.

The tray or surface (disposable plate) may be supplied in a sterilepackaging (similar to the syringe) to be affixed to the printer prior tothe printing process. It is desirable that the printing medium willslightly adhere to the printing surface or tray to prevent movement ofthe graft while printing. However, once completed, the graft must alsobe able to be easily freed from the printing tray.

In a preferred embodiment, the X-ray imaging machine 155 may be a ConeBeam 3 D camera such as, but not limited to, the model GX DP-700supplied by Gendex Dental Systems of Hatfield, Pa. In other embodiments,other imaging devices may be used such as, but not limited to, othercomputer aided tomography devices, cat-scan devices, 3-D laser camerasor a combination thereof.

FIG. 2 shows a magnified section of the mineral structure of bone.Mammalian bone may be composed of a bone mineral 215 having a lattice ormatrix of voids 220. Bone may typically be composed of 50 to 70%inorganic mineral, 20 to 40% organic collagen matrix, 5 to 10% water,and <3% lipids. The organic collagen, water, lipids and blood vesselsare typically contained within the voids. The inorganic mineral contentof bone is mostly hydroxyapatite [Ca.sub.10(PO.sub.4).sub.6(OH).sub.2].The inorganic mineral provides the mechanical strength and rigidity,whereas the organic collagen matrix provides elasticity and flexibility.

FIG. 3 shows a magnified section of a demineralized allograft bonematrix (DMB). The demineralized allograft bone matrix (DMB) 145 may bemade up of collagen 130, typically formed into a matrix structure, andbone morphogenetic proteins (BMP) 135. Bone morphogenetic proteins(BMPs) are a group of growth factors also known as cytokines and asmetabolomes. They were originally discovered through their ability toinduce the formation of bone and cartilage, and are now considered toconstitute a pivotal group of morphogenetic signals that may orchestratetissue architecture throughout the body. Although bone morphogeneticproteins (BMP) 135 may be manufactured by genetic engineering,demineralized allograft bone matrix (DMB) 145 is a favored source, andmay be used in a paste or putty to facilitate bone regeneration.Demineralized allograft bone matrix (DMB) 145, i.e., allograft bone thathas had inorganic minerals removed, may expose more bone morphogeneticproteins (BMP) 135 and therefore facilitate faster growth of naturalbone into the paste or putty. Demineralized allograft bone matrix (DMB)145 does not, however, have the strength of natural bone. Allograft boneis human bone, typically taken from cadavers and bone banks.

Demineralized allograft bone (DMB) 145 may be obtained from, forinstance, MAXXEUS Inc., of Kettering, Ohio who sells it under the brandname MAXXEUS® DBM PUTTY.

FIG. 4 shows a magnified section of a porous, biocompatible materialsuitable for use as a bone graft. The porous, biocompatible material 125may, for instance, be made up of a biocompatible, porous structuralsupport 250 made conducive to osteoinduction by the presence of bonemorphogenetic proteins (BMP) 135.

In a preferred embodiment, the biocompatible, porous structural support250 may, for instance, be porous Poly Methyl Methacrylate (PMMA) 140 andthe bone morphogenetic proteins (BMP) 135 may, for instance, bedemineralized allograft bone matrix (DBM) 145. The bone morphogeneticproteins (BMP) 135 may also, or instead, be a synthetically producedcompound such as, but not limited to, recombinant human BoneMorphogenetic Protein-2 (rhBMP-2) as provided by, for instance,Medtronic Inc. of Minneapolis, Minn. in their INFUSE Bone Graftmaterial.

Poly Methyl Methacrylate (PMMA) 140 is a synthetic polymer of methylmethacrylate, whose biocompatibility was, apparently, discovered byaccident during WWII when RAF pilots suffered eye injuries from thedestruction of their side widows. Hawker Hurricane pilots, whose windowswere made of glass, suffered severe rejection/infection in the vicinityof the glass splinters in their eyes, while Spitfire pilots, whose sidewindows were made of PMMA suffered no rejection/infection in thevicinity of the PMMA splinters. This good degree of compatibility withhuman tissue has been exploited by using PMMA for intraocular eye lensesthat replace cataract damaged lenses, and in orthopedic surgery. Inorthopedic surgery it is used as a grout, or bone cement, to stabilizejoin implants. PMMA bone cement such as, but not limited to, SIMPLEX P™BONE CEMENT sold by the Stryker Corporation of Kalamazoo, Mich. istypically supplied as a powder and a liquid. The ingredients ofStryker's SIMPLEX P™ BONECEMENT are reported to be 75% methylmethacrylate; 15% polymethylmethacrylate (PMMA); 10% Barium Sulfate forradio-opaqueness, and an undisclosed quantity of benzoyl peroxide toinitiate the radical induced polymerization of the MMA to PMMA. Theamount of the radical polymerization initiator, benzoyl peroxide, may becrucial for determining the mixing, handling, and settingcharacteristics of the bone cement.

In orthopedic use, the powder and liquid precursors are mixed about 10minutes before being used. Mixing the powder and liquid initiates thepolymerization, which may take up to several hours to complete. They areeither applied as putty, or delivered to the required site by means ofneedles that range in size from 10 to 14 gauges, i.e., in the vicinityof 2 mm internal bore needles.

FIG. 5 shows a magnified section of an intermediate stage in producingporous poly methyl methacrylate (PMMA).

The porous Poly Methyl Methacrylate (PMMA) 140 may be produced byincluding sucrose crystals 170 of the appropriate size in the MMA beingpolymerized. After the MMA is fully polymerized from its liquid form tosolid form, the sucrose crystals 170 may be dissolved out, leavingbehind a porous PMMA structure.

This method of producing a porous PMMA structure was developed in orderto overcome some shortcomings of existing PMMA bone cement, as reportedby A. Rijke et al in an article entitled “Porous Acrylic Cement”published in J Biomed Mater Res. 1977 May; 11(3):373-94, the contents ofwhich are hereby incorporated by reference.

Shortcomings of PMMA bone cement include that it heats up to82.5.degree. C. (160.5.degree. F.) while setting. This is high enough tocause thermal necrosis of neighboring tissue, or any biomaterial suchas, but not limited to, collagen and bone morphogenetic proteins (BMP)that may be found in demineralized allograft bone matrix (DMB).

By modifying the cement composition through the addition of soluble,nontoxic filler such as sucrose or tri-calcium phosphate which does notimpair the workability of the material during surgery, a significantimprovement in the performance of the cement can be achieved. Becausethe filler replaces part of the acrylic components, less heat isgenerated during curing while the filler itself acts as a heat sink.

Porous cement may be obtained provided that a critical minimumpercentage loading of the filler is exceeded so that the filler crystalswill make physical contact with each other. The value of this percentagedepends on both crystal modification and size. With crystals in the125-175 micron range, the critical minimum percentage may be in therange of 20-28 wt. % loading. Above 30%, the interconnecting pore sizeincreases and may allow good tissue ingrowth into the pores. Theintroduction of filler and pores may cause a drop in strength, but thetensile strength of modified cement containing up to 40% pores andsucrose lies between 0.7 and 1.5 kg/mm sup.2, which is in the same rangeas that of bone.

Poly methyl methacrylate (PMMA) may be made biodegradable by theaddition of cellulose acetate (CA) 255 or cellulose acetate phthalate(CAP) 260, as described in, for instance, an article by D. Batt et al.entitled “Biodegradability of PMMA Blends with Some CelluloseDerivatives”, published in Journal of Polymers and the Environment, Oct.2006, Volume 14, Issue 4, pp. 385-392, the contents of which are herebyincorporated by reference.

The rate of biodegradation may be controlled by the relative amount ofthe compound use to increase the biodegradability of the ink, or theproduct produced by the polymerized ink.

FIG. 6 shows a sematic layout of an ink mixing and print nozzle of apreferred embodiment of the present invention.

In a preferred embodiment, the ink may contain structural materialingredients; ingredients to form a porous, resorbable, matrix; andadditives such as, but not limited to, synthetic BMPs, antibioticchemicals, anti-inflammatory chemicals and radiopaque chemicals, or somecombination thereof.

The structural material ingredients may, for instance, include asubstance such as, but not limited to, Hydroxyapatite, allograftparticulate bone, xenograft particulate bone or some combinationthereof.

The ingredients to form a porous, resorbable matrix may includesubstances such as, but not limited to, methyl methacrylate, cellulose,resorbable cements, or precursors to resorbable cements or somecombination thereof.

Antibiotic additives may include any suitable antibiotic, or antibioticcombinations, such as, but not limited to, demeclocycline, doxycycline,minocycline, oxytetracycline, tetracycline, thiamphenicol,ciprofloxacin, enoxacin, gatifloxacin, levofloxacin, lomefloxacin,moxifloxacin, nalidixic acid, norfloxacin, ofloxacin, bacitracin,colistin, amoxicillin/clavulanate, ampicillin/sulbactam,piperacillin/tazobactam, ticarcillin/clavulanate, or some combinationthereof.

In a preferred embodiment, the ink may, for instance, be supplied in theform of a precursor powder 190 and a precursor liquid 195. These may befeed to separate containers in the 3-D printer. Prior to printing, aquantity of the precursor powder 190 and the precursor liquid 195 may bemixed to form the ink 150 to be used for printing the custom bone graft120. The printing may be accomplished by delivering quantities of theink 150 via a suitably sized print nozzle 235 that may be moved in araster scan 230 with respect to the custom bone graft 120 being printed.

The precursor powder 190 of the ink 150 may, for instance, contain avariety of ingredients such as, but not limited to, demineralizedallograft bone matrix (DMB) 145, sucrose crystals 170, radicalpolymerization initiator 175 or some combination thereof.

The radical polymerization initiator 175 may, for instance, be acompound such as, but not limited to, di-benzoyl peroxide (BPO).

The precursor liquid 195 may for, instance, contain a variety ofingredients such as, but not limited to, methyl methacrylate (MMA) 165,a radio-pacifier 185, an antibiotic 180, and a compound to increase thebiodegradability 265, or some combination thereof.

The radio-pacifier 185 may, for instance, be a compound such as, but notlimited to, zirconium dioxide (ZrO.sub.2) or barium sulphate(BaSO.sub.4) or some combination thereof.

The antibiotic 180 may, for instance, be a compound such as, but notlimited to, amoxicillin, doxycycline, gentamicin or clindamycin or somecombination thereof.

The compound to increase the biodegradability 265 may, for instance, bea compound such as, but not limited to, cellulose acetate (CA), orcellulose acetate phthalate (CAP) or some combination thereof.

FIG. 7 shows a sematic flow diagram of representative steps of apreferred embodiment of the present invention.

In Step 701 “Obtain 3-D Image of Graft Location”, the patient may beimaged using one of a number of well-known techniques for obtaining a3-D image such as, but not limited to, a cone beam 3-D camera, computeraided tomography, 3-D laser cameras, CT scan, or a combination thereof.

In Step 702 “Create 3-D Model of Custom Bone Graft”, the images obtainedin step 701 may be used by a suitably constructed computer programoperable on a suitable digital data processor, to generate a 3-D modelof a custom bone graft for the patient. In this step, the computerprogram may also use a database of standard models of human body partsto provide guidance on areas that may not be adequately described ordetailed by the 3-D images. The bone graft may be modeled on the watertight 3-D mesh created as the supporting scaffold to give the user aninsight as to the overall size, bulk, weight, etc. The term “watertight” is generally used to mean the mesh bears no holes, cracks ormissing features.

The custom bone graft may also include provision for locating fixationscrews that might be added using guidance from a qualified professional.Further, using the 3-D model, one may be able to plan or distribute thescrews required as to avoid anatomical structures, friction, or otherundesirable side effects from the screws. Fixation screws, includingtheir size, location and orientation may be designed on the computermodel by a competent expert. In other embodiments, the software orprogram automatically positions such screws and their desired positioncan be then confirmed by the doctor. Holes for drill sleeves may then bedesigned into the custom bone graft by the suitably constructed computerprogram for doctor approval. Sleeves may then be inserted into the bonegraft. The surgeon may then be supplied with directions and the drillsize and depth required for each fixation screws by the software orprogram. The drill may, for instance, incorporate a stop to prevent itpenetrating too deeply into the bone of the graft recipient, or intovital structures within the bone such as, but not limited to, arteries,veins or nerves. Once the holes are drilled, the sleeves may be removedand the fixation screws inserted by the surgeon to hold the graft inplace. The fixation screws may for instance be made of stainless steel,titanium or resorbable screws, and may be supplied with the graft.

In Step 703 “Mix Precursor Powder & Liquid to Form Ink”, precursors ofthe ink may be mixed in relatively small batches. The size of thebatches mixed into ink may depend on the print speed of the 3-D printer,the print nozzle size of the printer, and the constituents of theprecursors, as once mixed, the ink will begin to polymerize with theviscosity of the ink increasing with time. Only as much ink as may beused by the 3-D printer in the time the ink is deliverable by the printnozzle may be mixed at any one time. In some embodiments, preset ink orprinting medium is supplied to the user.

The software or program may select a particular size syringe, asdescribed above, for use in the printing process. Once printing is readyto begin, steps can be taken to ensure the printing process occurs understerile conditions. A protective hood will enclose the printing area andair brought into the enclosed environments will be subjected tofiltration by a medical grade HEPA filter. Air can further be removedfrom the enclosed area via a surgical vacuum.

As it is being printed, the mesh itself may be moved or rotated inrelation to a position of the printing nozzle. Preferably, when using anextrusion process (to melt or soften rods of printing medium) theoperating or printing temperature of this scaffold is about 60 degreesCentigrade to about 120 degrees Centigrade depending on the exactmaterial or combination of materials chosen.

The printing temperature may also be selected in response to the desiredsize of the print string to be deposited and/or the size of the apertureon the head of the printing nozzle. In some embodiments, such parameterscan be customized by the user, whereas in other embodiments the 3-Dprinter receives an input as to the desired parameters (print stringsize, print medium, etc.) and the 3-D printer calculates the operatingparameters such as temperature, print speed, etc.

Further, some grafts and/or implants may be sizable when compared toother implants and/or grafts. Such grafts and/or implants may need someelement of reinforcement. For example, the mesh or scaffold may beprinted around a titanium rod. The rod may be situated in such a waythat permits removal of the rod after implantation (and sufficientcell/bone growth) or may simply be configured to remain within the newlygrown bone. Overall, the layers are continually printed until the 3-Dprinter determines that the final layer has been reached.

In Step 704 “Final Layer Printed?” the 3-D printer may first check tosee if it has printed all the layers required to produce the custom bonegraft. These layers may have been provided by a programmed moduleoperative on a digital data processing device, and may be the 3-D modelof the custom bone graft reduced to consecutive slices that printed inthe correct order may result in the required custom bone graft.

In Step 705 “Print Next Layer”, the 3-D printer may, if the final layerhas not yet been printed, print the next layer. This may be done by, forinstance, moving the print nozzle in a raster fashion, depositing inkwhere required. The printing is preferably performed in a sterilizedenvironment as noted above.

In Step 707 “Post Print Processing of Graft”, once the 3-D printer hasprinted all the required layers that constitute the custom bone graft,the bone graft may undergo post print processing. Initially, the graftneeds to be separated from the printing plate. This post processing stepmay also, for instance, include actions such as, but not limited to,dissolving out the sucrose crystals to provide a porous structure andsterilization of the custom bone graft, infusing graft with allograft,xenograft, antibiotics, BMPs, or other materials to ensure reception andstimulate bone growth. In some embodiments such additives are done atthe printing stage by a multi-headed printer having such materialscontained in varying syringes or holding containers.

In Step 708 “Insert Custom Bone Graft at Intended Graft Location” theprinted and processed custom bone graft may now be inserted into thepatient at the intended graft location. The recipient site is exposedand the scaffold or graft can then be inserted into the recipient site.The doctor may use the predetermined drills into the pilot holes in thegraft. Metal or resorbable screws may be used to fix a position of thegraft. Further, the screws may be color coded and the color of thescrews may be selected by the software. Once the position is fullysecured, primary closure is completed and the surgery can then beresolved.

In alternate embodiments, the ink may include demineralized xenograftbone, synthetic bone substitutes, and other slow reabsorbingbiocompatible, bioactive adhesives.

Alternate formulations of the printing ink may, for instance, includeartificial bone substitutes such as, but not limited to, hydroxyapatite,synthetic calcium phosphate ceramic. These may be used instead of, orwith natural bone particulates such as, but not limited to, allograftparticulate bone, or xenograft particulate bone, or some combinationthereof. These may, for instance, be used with synthetically producedbone morphogenetic agents such as, but not limited to, recombinant humanBone Morphogenetic Protein-2 (rhBMP-2).

Alternate inks may also, or instead, use other biocompatible, bio-activeadhesives such as, but not limited to glass polyalkenoate cements, oleicmethyl ester based adhesives, or some combination thereof.

Although producing the custom bone grafts has been discussed withrespect to 3-D printing, some or all of the machining of the custom bonegrafts may be done using more conventional machining such as computernumerical control (CNC) milling, drilling or routing machines. The holesfor the fixation screws may, for instance, be drilled by CNC machineafter the custom graft is produced, or support structure necessaryduring the printing of a complex shape may be removed by CNC machining,or a starting template may be CNC machined from natural or syntheticbone material to reduce the printing time of the entire custom graft.

In order to do such machining the digital processor 240 may generate a3-D model in a suitable computer language such as, but not limited to,G-code that may enable a CNC machine to machine a block of bonesubstitute material. The block of bone material may, for instance, be amaterial such as, but not limited to, REPROBONE® material as supplied byCeraymisys, Ltd. of Sheffield, England. The material used to create thecustom bone graft may also, or instead, be a calcium phosphate materialsuch as, but not limited to, hydroxyapatite.

In a preferred embodiment, the machining may, for instance, beaccomplished using a multi-axis CNC milling machine such as, but notlimited to, a LAVA™ CNC 500 milling system manufactured by 3M ofMinneapolis, Minn.

In a further preferred embodiment of the invention, a semipermeable,resorbable membrane may be printed on top of the bone graft using asecond ink. Such a membrane may, for instance, be made of a co-polymericblend of poly-vinyl alcohol (PVA) and poly-vinyl pyrrolidone (PVP), asdiscussed in, for instance, U.S. Pat. No. 7,476,250 issued to Mansmannon Jan. 13, 2009 entitled “Semi-permeable membranes to assist incartilage repair”, the contents of which are hereby incorporated byreference. The semipermeable, resorbable membrane may, for instance, beextend beyond the perimeter of the bone graft in some or all portions ofthe perimeter, by an amount that may be as much as 1 cm, but is morepreferably 0.5 cm.

In yet a further preferred embodiment of the invention, a custom bonegraft 120 may be produced using a graft negative mold 305. The graftnegative mold 305 may, for instance, be generated using a 3-D digitalgraft model 310 produced from a 3-D image 105 obtained using a X-rayimaging machine 155 such as, but not limited to, a cone-beam X-rayimaging machine 315.

FIG. 8 shows a cone-beam X-ray imaging machine 315 to perform a scan ofa patient 320. A cone-beam X-ray imaging machine 315 typically containsan X-ray generator 325 and a digital X-ray sensor 330. The X-raygenerator 325 and the digital X-ray sensor 330 may, for instance, behoused at opposite extremities of a C-shaped housing 335. The X-raygenerator 325 may emit a conical beam of X-rays 340 as the C-shapedhousing 335 is rotated 345 around the patient 320. The data captured bythe digital X-ray sensor 330 may then be sent to a digital computer 350that may be running suitable software to convert that data into a 3-Dimage 360 of a bone defect 355 aka an intended graft location 370. The3-D image 360 of a bone defect may, for instance, be displayed on adigital display 365.

FIG. 9 shows a sectional view of a 3-D image 360 of a bone defect suchas, but not limited to, bone and/or cartilage tissue lost to trauma,surgery, infection, normal aging or anatomic abnormalities due to anypathology. This method may, for instance, be useful in oralmaxillofacial surgery, dental implants, orthopedic surgery or any typeof reconstructive hard tissue surgery.

FIG. 10 shows a sectional view of a computer generated 3-D positiveimage 375 of a required custom bone graft 120 to be located at a bonesite 395.

In a preferred embodiment, the 3-D positive image 375 of a requiredcustom bone graft may also include additional requirements such as, butnot limited to, any required locating screws 380, or guide paths forscrews or tacks to fix the graft in place, space for adhesive 385 andany required structural reinforcement 390, or guide holes to accommodatereinforcement pins, or some combination thereof.

FIG. 11 shows a sectional view of a computer generated model of anegative mold 405 of a required graft. The negative mold 405 may, forinstance, include a top of a negative mold 410, a left bottom of anegative mold 415, and a right bottom of a negative mold 420, or somecombination thereof. The negative mold 405 of a required graft may, forinstance, include suitable relief vent holes 425, locating cones 430, orsome combination thereof. The top of a negative mold 410 may, forinstance, be also include suitable locating keys 435 or guide paths foradditions such as, but not limited to, locating screws or tacks 380,structural reinforcement pins 390 or some combination thereof.

In a preferred embodiment, the negative mold 405 of a required graft maybe made using a 3-D printer and suitable polymers or photopolymers. Thenegative mold 405 of a required graft may also be made, wholly or inpart, using a CNC machine such as, but not limited to, a CNC router, ora combination of 3-D printing and CNC machining.

FIG. 12 shows a sectional view of a negative mold being used to producea required graft. The negative mold 405 of a required graft may, forinstance, be first coated with a suitable release agent 440 and anynecessary place holders 450 for any structural reinforcement 390 orlocating screws 380 or a combination thereof. An FDA approved, porous,biodegradable, biocompatible material 445 that is conducive toosteoinduction and has a load bearing strength comparable to bone, toproduce said custom bone graft may then be poured, placed or insertedinto the negative mold 405 of a required graft.

The materials used in producing the customized bone graft from thenegative mold may include any of the appropriate materials, andcombinations of materials, described above such as, but not limited to,demineralized allograft bone matrix (DMB), or porous Poly MethylMethacrylate (PMMA) 140 and recombinant human Bone MorphogeneticProtein-2 (rhBMP-2), or some combination thereof.

In a preferred embodiment of the present invention, the material may bea mixture such as, but not limited to, Calcium Sulfate hemihydrate, akaPlaster of Paris, demineralized freeze dried bone (DFDB), or freezedried bone (FDB), Bone Morphogenetic Proteins (BMP) and an antibioticsuch as, but not limited to, Odxucicline.

Further materials including, but not limited to, solidifying resorbableor non resorbable possibly osteoconductive, osteoinductive medium thatmay be placed inside the negative mold. Such a medium may, for instance,be a medium such as, but not limited to, polymethylmethacrylate (PMMA),Fibrin Glue, Hydroxyapatite cements or Bio-glass or some combinationthereof. Other biomaterials such as, but not limited to, coral,bone-derived materials, bioactive glass ceramics, and synthetic calciumphosphate that may have been mixed with fibrin sealant bone graftingmaterial that may be added by an operator (any particulate materialavailable may function) as well as BMPs, antibiotics or other additivesdeemed necessary. Material that may be in excess of the required amountmay be placed so as to accommodate any resorption of the graft. Thenegative lid may be placed by, for instance, guiding cones that mayengage negative mold cone holes. Excess material may be squeezed out ofthe negative lid through suitably place relieve vents and be removedwhile the bone graft is still in a gelatinous, or liquid state.

The porous, biodegradable, biocompatible material 445 may be allowed to,or induced to, set, thereby creating a required custom bone graft 120.

FIG. 13 shows a sectional view of a graft being placed during surgery.The intended graft location 370 may first be coated with a bone adhesive455. The custom bone graft 120, including any necessary structuralreinforcement 390 that may be incorporated into it, may then be placedin the intended graft location 370. The custom bone graft 120 may thenbe secured in the intended graft location 370 by a suitable means suchas, but not limited to, one or more locating screws 380 or tacks, thatmay be bio-inert and may be bio-absorbable. The structural reinforcement390 and locating screws 380 are preferably biocompatible and may bebiodegradable. Suitable biocompatible materials include compositionssuch as, but not limited to, plastics such as PMMA and stainless steel,polygluconate co-polymer (PGACP) or self-reinforced poly-L-lactic acidpolymer (PLLA) or some combination thereof.

FIGS. 14A-D are illustrative of steps that may be used in the process offabricating a required complex long bone graft 460.

FIG. 14A shows a required complex long bone graft that may be required460.

FIG. 14B shows a negative mold for a portion 465 of the required complexlong bone graft 460. In the instance shown in FIG. 14 B, the negativemold is designed to produce one half of the bone graft. The negativemold may include a top of a negative mold 410, a left bottom of anegative mold 415 and a right bottom of a negative mold 420 as well aslocating cones 430 and corresponding locating indents 470, and ventholes 425.

FIG. 14C shows a negative mold being used to produce a portion of therequired complex long bone graft. The negative mold 405 of a portion ofthe required graft, containing any required structural reinforcement390, may have been coated with a suitable release agent and then filledwith an appropriate porous, biocompatible material 125.

FIG. 14D shows a complex long bone graft 460 composed of two portions465 of the bone graft that may contain structural reinforcements 390 andheld together by one or more locating screws 380.

Referring now to FIGS. 16A and 16B, there are illustrationsdemonstrating at least two potential printing methodologies for thescaffold or mesh construction. In FIGS. 16A-B, there is a perspectiveand top view of a rotation printing methodology. In FIG. 16C, there is aside view of a sidestepping printing methodology demonstrating aninterconnection of a porous grid.

In FIG. 16A, the layers are shown to be printed with three layersaligned with one another forming single tier and three layers rotatablyshifted and aligned with one another forming alternating tier. The twosets of directionally positioned layers are situated upon one another.The number of layers comprising each “layer” before the rotation occursmay vary and may be from about one layer to about twenty five layers.The amount of rotation may also vary and is preferably at least45.degree. in relation to the layer(s) located below the layers ofrotation.

In FIG. 16B, the layers are shown to be printed with three layersaligned with one another forming single tier and three layers shiftedforming alternating tier. Here, the layers have not been rotated but theconnection points forming the lattices have been shifted in relation toa predetermined “layering” of the printing medium. As shown, the bottomthree layers and the top three layers are aligned in terms of printingpattern with the connection points of the lattices aligned with oneanother. The middle three layers have these connection points shifted tobe somewhere within the distance formed between a first set and a secondset of connection points. The spacing of the connection points and thelocation of the interspersed (shifted) layers between these points mayvary as desired. As described above, the number of layers may also varyas desired.

Preferably, there are alternating tiers layered on top of each otheruntil they fill graft vertically. Horizontal form of the graft isprinted based on form of the 3D model.

Each of the above printing methodologies outlined in FIGS. 16A-B, andothers not explicitly described herein, are configured and designed topromote maximum vascular and neural growth within the graft (see FIG.16C). This allows full vascular and neural penetration in to thegrafting material which is disposed on to the rigid scaffold or meshdescribed herein.

Although this invention has been described with a certain degree ofparticularity, it is to be understood that the present disclosure hasbeen made only by way of illustration and that numerous changes in thedetails of construction and arrangement of parts may be resorted towithout departing from the spirit and the scope of the invention.

I claim:
 1. A system for producing a custom bone graft, comprising: anX-ray imaging machine for obtaining a three-dimensional image of anintended graft location; a digital processor for creating athree-dimensional digital model of said custom bone graft using saidthree-dimensional image; and a three-dimensional printer for printingsaid custom bone graft using said three-dimensional digital model and aprinting medium, said three-dimensional printer comprising: a steriledisposable print surface; a sterile syringe for injecting said printingmedium; and a hood for enclosing said three-dimensional printer, whereinsaid hood is coupled to a medical grade high efficiency particulate airfilter, and wherein sterile air is drawn into said hood via said highefficiency particulate air filter and removed via a surgical-typesuction connection; wherein said three-dimensional printer prints saidcustom bone graft in a sterile environment by depositing said printingmedium layer by layer on said sterile disposable print surface, whereinafter printing a predetermined number of layers, said print surface isrotated or side-stepped before printing next set of said predeterminednumber of layers, wherein said rotation and side-stepping processespromote maximum vascular and neural growth within said created custombone graft, and wherein said sterile custom bone graft is adapted fordirect insertion at said intended graft location without additionalsterilization procedure.
 2. The system of claim 1, wherein said printingmedium comprises polycaprolactone (PCL), polylactic acid (PLLA),polylactic-co-glycolic acid (PLGA) or other food and drug administrationapproved resorbable, biodegradable materials.
 3. The system of claim 2,wherein said printing medium preferably comprises polycaprolactone(PCL).
 4. The system of claim 1, wherein said printed custom bone graftincludes provision for locating fixation screws.
 5. The system of claim1, wherein said three-dimensional printer calculates operatingparameters comprising temperature and print speed based on size of saidcustom bone graft to be printed and type of said printing medium used.6. The system of claim 1, further comprising infusion of said custombone graft with allograft, xenograft, antibiotics or bone morphogeneticproteins (BMP) to ensure reception of said custom bone graft at saidintended graft location and to stimulate bone growth at said intendedgraft location.
 7. A system for producing a custom bone graft,comprising: an X-ray imaging machine for obtaining a three-dimensionalimage of an intended graft location; a digital processor for creating athree-dimensional digital model of said custom bone graft using saidthree-dimensional image; and a three-dimensional printer for printingsaid custom bone graft using said three-dimensional digital model and aprinting medium, wherein said printing medium is a solid rod, andwherein said three-dimensional printer comprises: a sterile disposableprint surface; a sterile syringe for injecting said printing medium; anda hood for enclosing said three-dimensional printer, wherein said hoodis coupled to a medical grade high efficiency particulate air filter,and wherein sterile air is drawn into said hood via said high efficiencyparticulate air filter and removed via a surgical-type suctionconnection; wherein said three-dimensional printer prints said custombone graft in a sterile environment by melting and depositing said solidrod layer by layer on said sterile disposable print surface by anextrusion deposition method, wherein after printing a predeterminednumber of layers, said print surface is rotated or side-stepped beforeprinting next set of said predetermined number of layers, wherein saidrotation and side-stepping processes promote maximum vascular and neuralgrowth within said created custom bone graft, and wherein said sterilecustom bone graft is adapted for direct insertion at said intended graftlocation without additional sterilization procedure.
 8. The system ofclaim 7, wherein said printing medium comprises polycaprolactone (PCL),polylactic acid (PLLA), polylactic-co-glycolic acid (PLGA) or other foodand drug administration approved resorbable, biodegradable materials. 9.The system of claim 8, wherein said printing medium preferably comprisespolycaprolactone (PCL).
 10. The system of claim 7, wherein said printedcustom bone graft includes provision for locating fixation screws. 11.The system of claim 7, wherein said three-dimensional printer calculatesoperating parameters comprising temperature and print speed based onsize of said custom bone graft to be printed and type of said printingmedium used.
 12. The system of claim 7, further comprising infusion ofsaid custom bone graft with allograft, xenograft, antibiotics or bonemorphogenetic proteins (BMP) to ensure reception of said custom bonegraft at said intended graft location and to stimulate bone growth atsaid intended graft location.